Calcium sensitive non-selective cation current promotes seizure-like discharges and spreading depression in a model neuron.

As described by others, an extracellular calcium-sensitive non-selective cation channel ([Ca(2+)](o)-sensitive NSCC) of central neurons opens when extracellular calcium level decreases. An other non-selective current is activated by rising intracellular calcium ([Ca(2+)]( i )). The [Ca(2+)](o)-sensitive NSCC is not dependent on voltage and while it is permeable by monovalent cations, it is blocked by divalent cations. We tested the hypothesis that activation of this channel can promote seizures and spreading depression (SD). We used a computer model of a neuron surrounded by interstitial space and enveloped in a glia-endothelial "buffer" system. Na(+), K(+), Ca(2+) and Cl(-) concentrations, ion fluxes and osmotically driven volume changes were computed. Conventional ion channels and the NSCC were incorporated in the neuron membrane. Activation of NSCC conductance caused the appearance of paroxysmal afterdischarges (ADs) at parameter settings that did not produce AD in the absence of NSCC. The duration of the AD depended on the amplitude of the NSCC. Similarly, NSCC also enabled the generation of SD. We conclude that NSCC can contribute to the generation of epileptiform events and to spreading depression.

Computer simulations of neuron-glia interactions mediated by ion flux.

Extracellular potassium concentration, [K(+)](o), and intracellular calcium, [Ca(2+)](i), rise during neuron excitation, seizures and spreading depression. Astrocytes probably restrain the rise of K(+) in a way that is only partly understood. To examine the effect of glial K(+) uptake, we used a model neuron equipped with Na(+), K(+), Ca(2+) and Cl(-) conductances, ion pumps and ion exchangers, surrounded by interstitial space and glia. The glial membrane was either "passive", incorporating only leak channels and an ion exchange pump, or it had rectifying K(+) channels. We computed ion fluxes, concentration changes and osmotic volume changes. Increase of [K(+)](o) stimulated the glial uptake by the glial 3Na/2K ion pump. The [K(+)](o) flux through glial leak and rectifier channels was outward as long as the driving potential was outwardly directed, but it turned inward when rising [K(+)](o)/[K(+)](i) ratio reversed the driving potential. Adjustments of glial membrane parameters influenced the neuronal firing patterns, the length of paroxysmal afterdischarge and the ignition point of spreading depression. We conclude that voltage gated K(+) currents can boost the effectiveness of the glial "potassium buffer" and that this buffer function is important even at moderate or low levels of excitation, but especially so in pathological states.

Vesicular cholesterol in bile. Relationship to protein concentration and nucleation time.

A study was done to determine whether the nucleation time was related to the amount of cholesterol carried in vesicles. Bile was obtained from cholesterol gallstone patients and controls. Gel-exclusion chromatography was used to separate vesicles and micelles in the native bile using an eluting buffer containing 10 mM sodium cholate. The percent of total cholesterol carried in vesicles in gallbladder bile of stone patients was significantly greater than that in control patients. Total cholesterol concentration in gallbladder bile of stone patients was significantly greater than in controls. This difference was due to the fact that vesicular cholesterol concentration was significantly greater in the gallbladder bile of stone patients compared to controls. Micellar cholesterol concentrations were similar in the two groups. Nucleation time was related significantly to vesicular cholesterol concentration in correlation analysis and, as previously shown, so was total protein concentration. This study supports the importance of vesicular cholesterol in solid crystal formation and demonstrates for the first time that the rate of cholesterol monohydrate crystal formation is directly related to the amount of cholesterol transported in vesicles.

Cholesterol-phospholipid vesicles in human bile: an ultrastructural study.

Phospholipid vesicles, a newly described (bile salt independent) mode of cholesterol transport in human bile, were previously characterized by quasi-elastic light scattering and gel filtration. In the present study the ultrastructure of these vesicles was investigated by electron microscopy using freeze-fracture and negative-staining techniques. Vesicles of varying size were found in all 14 hepatic and 3 gallbladder biles examined. The diameter of the vesicles ranged from 25 to 75 nm by electron microscopy after freeze fracture and from 54 to 94 nm by quasi-elastic light scattering. They had a spherical shape and appeared to be unilamellar. The appearance of the vesicles in fresh hepatic and gallbladder biles as well as in chromatographic fractions was similar. Vesicles were dissolved by the addition of exogenous bile salts. Cholesterol is transported in human bile by both vesicles and micelles. The role of the vesicles may be particularly important in preventing cholesterol precipitation in dilute and supersaturated biles.

Increased saturation of the fatty acids in the sn-2 position of phospholipids reduces cholesterol crystallization in model biles.

Changes in the molecular structure of biliary phospholipids were shown to have major effects on cholesterol solubility, carriers and crystallization in human and model biles. This study investigated systematically the effects of varying saturation of the phosphatidylcholine (PC) sn-2 fatty acid on the cholesterol crystallization process in 3 different model biles. Twenty % of the egg PC (EPC) in these biles were replaced by synthetic PC's with 16:0-18:0, 16:0-18:1, or 16:0-18:2 fatty acyl chains. With 18:0 in the sn-2 position, the crystal observation time (COT) was prolonged from 2 days in the control EPC solution to 14 days (p<0.05). The crystal growth rate (CGR) was reduced from 0.1 OD/day to unmeasurable levels, and the total crystal mass on day 14 decreased by 86%. The introduction of one (18:1), and two (18:2) double bonds in the sn-2 fatty acid rapidly reversed these effects. Ultracentrifugal analysis showed precipitable cholesterol as monohydrate crystals. In the 16:0-18:0 test solution, most of the precipitable cholesterol remained in the supersaturated multilamellar vesicles. Saturation of the biliary PC sn-2 fatty acyl chain prolongs the COT, slows the CGR, reduces the crystal mass, and extends cholesterol solubility in multilamellar vesicles. Desaturation of the sn-2 fatty acid reverses these effects.

Demonstration of 8 S-cytoplasmic oestrogen receptor in rat mullerian duct.

1. High affinity macromolecular binding of the non-steroidal synthetic oestrogen [3H]diethylstilboestrol and of [3H] oestradiol-17beta in cytosol of Müllerian duct and uterus, and in blood plasma of perinatal rats, was investigated by sucrose density gradient sedimentation. 2. While [3H] oestradiol was bound to both the characteristic 8 S uterine cytoplasmic receptor and a 4 S component of uterine cytosol and plasma of 11-day-old rats, [3H] diethylstilboestrol was bound almost exclusively by the 8 S cytoplasmic receptor. 3. The greatly reduced binding of [3H] diethylstilboestrol to the 4 S plasma plasmic receptor in the Müllerian duct (precursor of the uterus) of 20-day-old foetuses.

Quantitation of phospholipid vesicles and their cholesterol content in human bile by quasi-elastic light scattering.

The proportion of biliary cholesterol carried by phospholipid vesicles may be an important determinant of the lithogenicity of bile. The distribution of biliary cholesterol between vesicles and other aggregational forms is often determined by gel filtration under standard conditions. The aim of this study was to measure the proportion of biliary cholesterol in vesicles in native unprocessed bile and to compare it with values obtained by chromatography. A modified quasi-elastic light-scattering method was used to measure vesicular cholesterol in whole bile. It was suitable only for lightly pigmented biles with a relatively monodisperse population of vesicles. In ten human biles examined, the proportion of cholesterol in vesicles by gel filtration was 40 +/- 8.1% (mean +/- S.D.) by chemical measurement, and 38 +/- 7.2% by [3H]cholesterol estimation. Quasi-elastic light-scattering measurements of these biles produced vesicular cholesterol values of 36 +/- 9.4%. Chromatography may affect lipid particles in bile. Nevertheless, it provides a relatively accurate measurement of biliary cholesterol in vesicles.

Nucleation of cholesterol from vesicles isolated from bile of patients with and without cholesterol gallstones.

Bile was obtained from patients with and without cholesterol gallstones at surgery. Biliary vesicles were separated from micelles by gel filtration. The cholesterol/phospholipid ratio in vesicles was much higher than in micelles. Cholesterol crystals nucleated from vesicular fractions, but nucleation from the micellar fractions was slow or did not occur at all. Cholesterol nucleated from vesicles obtained from bile of control patients as rapidly (2.4 days +/- 0.7) as from patients with stones (2.4 days +/- 0.9) and there was no difference in the vesicular cholesterol/phospholipid ratio. The effect of alteration of the bile salt environment was studied by changing the concentration of sodium cholate in the eluting buffer. At low concentrations (5 mM) only vesicles were eluted from the column. These vesicles had a relatively low cholesterol/phospholipid ratio and cholesterol nucleated slowly from these vesicles. At higher concentrations the proportion of micelles increased. The proportion of vesicles decreased progressively but their cholesterol/phospholipid ratio increased and the nucleation time fell. These studies demonstrate that cholesterol nucleates from vesicles in the absence of micelles, that control vesicles are not protected by tightly bound antinucleating substances and that exposure of vesicles to micelles strips relatively more phospholipid than cholesterol from the vesicular fraction, resulting in vesicles with higher cholesterol/phospholipid ratios and shorter nucleation times.

Phospholipid lamellae are cholesterol carriers in human bile.

Cholesterol solubility and precipitation in bile are major factors in the pathogenesis of cholesterol gallstones. At present, mixed micelles and phospholipid vesicles are considered to be the only cholesterol carriers in bile. In this study we present evidence showing that phospholipid lamellae are major cholesterol carriers in human bile. Lamellae are a known aggregational form in pure phospholipid model systems. In the present study, lamellae were demonstrated by electron microscopy after negative staining and by small-angle X-ray diffraction in all human gallbladder bile samples examined. During diffraction experiments, cholesterol was found to crystallize from these lamellae. Cholesterol carriers in bile were separated by high-resolution chromatography and by prolonged ultracentrifugation. Lamellae were shown to solubilize most of the biliary cholesterol; vesicles solubilized a lesser amount; while micelles solubilized only a minor portion. Our data suggest that phospholipid aggregates are the main cholesterol carriers in bile. Bile salts may control the equilibrium between the various aggregational forms of cholesterol-carrying phospholipids.

Hypertonic environment prevents depolarization and improves functional recovery from hypoxia in hippocampal slices.

Treatments that postpone hypoxic spreading depression (SD)-like depolarization (also called anoxic depolarization) facilitate recovery of function after transient cerebral hypoxia. Hypertonia reduces cerebral excitability, and we tested whether it also offers protection against SD-like depolarization and hypoxia. Oxygen was withdrawn from hippocampal slices bathed in normal artificial cerebrospinal fluid (ACSF) and, simultaneously, from slices cut from the same hippocampus but bathed in strongly hypertonic ACSF. Extracellular osmolarity (pi(o)) was increased by adding 100 mM mannitol or fructose to ACSF. Slices in normal pi(o) underwent SD-like negative extracellular voltage shift (delta Vo). The hypertonic slices usually showed no SD-like delta Vo but only a small, gradual negative voltage shift. Hypertonia also prevented the precipitate drop of interstitial calcium level ([Ca2+]o). When oxygenation and normal osmolarity were restored, synaptic transmission in the previously hypertonic slices recovered completely, but 3 h after reoxygenation orthodromically transmitted population spikes of the control slices recovered only 25.1% of the initial control amplitude. We conclude that hypertonic treatment during hypoxia improves subsequent recovery of synaptic function. The protection is probably due to the prevention of calcium uptake by blocking the SD-like depolarization, with the prevention of hypoxic cell swelling playing a lesser role.

A non-micellar mode of cholesterol transport in human bile.

Quasi-elastic light scattering (QELS) was used to measure particle size in fresh human hepatic bile of 14 subjects. Particles with an approximate diameter of 700 A were found in all biles. The particles were almost unchanged after the bile salt concentration was reduced to 0.06 mM by dilution or dialysis against 150 mM NaCl. During dialysis bile salts were removed, while cholesterol and phospholipids remained in solution apparently in the large particles-vesicles. These experiments suggest the presence of a novel, bile salt-independent, mode of cholesterol transport in saturated human bile.

The induction of lamellar stacking by cholesterol in lecithin-bile salt model systems and human bile studied by synchrotron X-radiation.

Small angle X-ray scattering (SAXS) with synchroton radiation was used to investigate interactions among lipid particles in lecithin-bile salt model systems and in native gallbladder biles. In model systems in the absence of cholesterol, isotropic, continuous spectra were found, indicating the absence of periodic structures. In the presence of excess cholesterol, interaction in the form of lamellar stacking was detected by the appearance of discrete diffraction peaks. In the supersaturated cholesterol region of the commonly accepted phase diagram [1], where cholesterol crystals were expected, we found lamellar stacking. The high proportion of cholesterol to bile salts seems to be the common denominator of these models. The lamellar stacking was also found in native unprocessed bile. This effect of cholesterol on lipid structure has not been previously described. Lamellar stacking may contribute to cholesterol solubilization. Its influence on the kinetics of cholesterol crystallization is presently unknown.

Whole-cell membrane current and membrane resistance during hypoxic spreading depression.

In rat hippocampal tissue slices we recorded extracellular potential (Vo) and whole-cell patch clamp current of CA1 pyramid cells. During hypoxic spreading depression (SD)-like depolarization, the holding current (Ih) increased sharply. Membrane 'slope' resistance (Rm) decreased to 10-67% (mean 39%) of the resting value. The SD-related membrane current (ISD) reversed near zero mV. With voltage dependent K+ and Na+ currents blocked by Cs+ and QX-314, shifts of Ih and decrease of Rm during SD were not suppressed. We conclude that hypoxic SD of CA1 pyramidal cells is associated with a large non-selective inward current through yet to be identified membrane mechanisms, which cannot fully explain the SD-related Vo shift.

Pathophysiology of the spinal cord studied in vitro.

We describe the use of isolated hemisected mouse spinal cords for pathophysiological investigations and analyze the responses evoked and recorded with suction electrodes in spinal roots. Dorsal root (DR) recordings from preparations in control solution show a directly evoked fiber volley (FV); an early postsynaptic spike generated by neurons in spinal gray matter and picked up by volume conduction (DRR1); and a 'slow' dorsal root potential (DRP). The 'conventional' dorsal root reflex (here termed DRR2) was absent or very small in control medium but became very prominent in elevated bath [Ca2+]. DRP and DRR2 but not DRR1 are depressed by GABAA antagonists. Recordings from VR contain the electrotonically conducted VRepsp and superimposed monosynaptic reflex discharge (VRR1). Rarely in control medium but regularly in elevated bath [Ca2+] a GABA-dependent late reflex (VRR2) appears (see also Duchen, 1986). The effects of varying bath concentrations of K+, Ca2+ and Mg2+ on evoked responses are briefly summarized. Irregularly timed spontaneous discharges appear in DR and VR recordings when [Ca2+] is elevated above 1.8 or 2.4 mM, and when [Mg2+] is lowered to 0.4 mM. In hypoxic solution synaptically transmitted responses fail in 10 to 20 min, but persist longer when [Ca2+] is elevated. Unexpectedly, spreading depression (SD)-like responses were recorded in some preparations during hypoxia. Following hypoxia, after synaptically transmitted responses recovered, spontaneous activity developed in DR and VR recordings.

Enhancement of persistent sodium current by internal fluorescence in isolated hippocampal neurons.

Following up on an earlier chance observation, voltage-dependent whole-cell currents were recorded from isolated hippocampal neurons filled with the fluorescent dyes Fluo-3 and Fura-red, that were intermittently excited by 488 nm laser light. In the absence of any ion channel blocking drugs, in most cells depolarizing voltage steps initially evoked only the 'Hodgkin-Huxley' type early, fast inward surge followed by sustained outward current. Over 5-20 min of intermittent electrical stimulation and laser-excited fluorescence pulses, a voltage-dependent, slowly inactivating inward current also appeared and grew, while sustained outward current diminished. When K(+) currents were blocked, a small persistent inward current was usually detectable immediately, and then it increased in amplitude. This current was blocked by tetrodotoxin (TTX) and it had current-voltage (I-V) characteristics of a persistent sodium current, I(Na,P). In cells not filled with dye but illuminated by laser, and in cells with dye but not illuminated, I(Na,P) remained small. There was a more than 12-fold difference in the maximal amplitude of I(Na, P) of fluorescent compared to non-fluorescent cells. Once induced, I(Na,P) decreased very slowly. Fluorescence increased the duration but not the amplitude of the transient Na(+) current, I(Na,T). With membrane potential clamped to a constant voltage, the laser-induced fluorescence did not evoke a membrane current. It is not certain whether fluorescence-induced I(Na,P) potentiation is related to photodynamic action.

Acidification of interstitial fluid in hippocampal formation caused by seizures and by spreading depression.

Changes in the pH of interstitial fluid were measured with H+-selective double-barreled micropipette electrodes in fascia dentata of urethane-anesthetized rats. Paroxysmal afterdischarges provoked by repetitive stimulation of an afferent fiber tract brought in their wake acidification by 0.07 to 0.2 pH units. Spreading depression caused acidification by 0.2-0.5 pH units. Acid shifts were often preceded by transient alkalinization. Acidification is attributed to the production of CO2 and of other acid metabolites.

Calcium dependence of synaptic transmission in the hippocampal slice.

'Population' afferent spike and 'population' EPSP were recorded with extracellular microelectrodes in slices of hippocampal tissue maintained in vitro. Calcium concentration was changed in the bathing solution, and calcium activity ([Ca2+]0) was measured in interstitial fluid of the slice with ion-selective microelectrodes. Synaptic transfer was a non-linear continuous function of [Ca2+]0. Deviation of [Ca2+]0 by 0.1 mM from the 1.2 mM control level caused a change of approximately 15% in the slope of the input-output function.

Low external NaCl concentration and low osmolarity enhance voltage-gated Ca currents but depress K currents in freshly isolated rat hippocampal neurons.

In previous experiments, reducing bath osmolarity (pi o) or external NaCl concentration ([NaCl]o) caused an increase in synaptic currents recorded in whole-cell configuration from pyramidal cells of CA1 region of hippocampal slices. Slow inward current surges, assumed to be calcium currents, were also enhanced. This contrasted with the strong, reversible, generalized depression of voltage-dependent ion currents in isolated neurons, caused by sudden, brief exposure to very low pi o. I have now recorded voltage-dependent whole-cell Na-, K- and Ca-currents from freshly isolated hippocampal CA1 pyramidal neurons during more gradual lowering of pi o or [NaCl]o. Changes in cell size were determined from image areas and changes in intracellular Ca2+ activity were measured as the ratio of the fluorescences of fluo-3/fura-red by confocal microscopy. Iso-osmotic substitution of 40 or 60 mM NaCl by mannitol or sucrose for 5-7 min, or reducing pi o by deleting NaCl from the bath (osmolarity decreased by 69 or 108 mosM/kg) depressed K currents. Na currents were also strongly depressed, but this is in part attributable to reduced driving potential and ionic conductance. The depression of IK varied widely and it was inversely correlated with the degree of hypotonic swelling, suggesting that reduced ion channel conductance also reduces permeability to water. Reducing [NaCl]o by 60 mM, or pi o by 105 mosM/kg consistently and reversibly increased Ca currents. Intracellular Ca2+ level also increased, but the changes of [Ca2+]i and ICa were not correlated. Facilitation of the Ca influx into presynaptic terminals could explain the increase of synaptic currents. Depression of outward currents could also contribute to the irritability of the central nervous system typical of clinical hyponatremia.